RU2279011C2 - Line compressor station - Google Patents

Abstract

FIELD: gas industry.

SUBSTANCE: invention can be used in compressor stations designed for increasing pressure of natural gas in transportation. Proposed line compressor station of gas pipeline is installed on section of gas main after head compressor station between head station and other line compressor station or between line compressor stations. Said line compressor station includes gas transfer sets connected at inlet by process pipings with preparation system of at least process gas, and at outlet, with process gas cooling plant and, through shutoff valves, supply and outlet pipelines, with gas main. Cooling plant of process gas is furnished with at least one air gas cooling device consisting of at least two heat exchange sections whose heat exchange section has multirow bank of ribbed single-pass pipes forming, within the limits of each row in projection onto conventional plane normal to vector of flow of heat exchange medium-cooling air fed to pipes and passing through central longitudinal axes of pipes of each row, sections of complete aerodynamic nontransparency corresponding to projections onto said plane of pipes, neglecting their ribbing, sections of complete aerodynamic transparency corresponding to projections on said plane of clearances between edges of ribs pointed to each other in row of adjacent pipes, and section of incomplete aerodynamic transparency limited, each, from one side by conventional straight line passing over tops of ribs, and at other side, by contour of pipe body over rib bases. Specific ratio per unit of rate of said conventional plane of summary areas of projections of said sections with different aerodynamic transparency in each row is respectively (0.85-1.15):(1.82-2.17):(1.80-2.19).

EFFECT: improved efficiency of compressor station, reduced labor input and cost of manufacture at high heat exchanger characteristics and reliability of operation owing to optimization of parameters of bank of ribbed heat exchange pipes.

11 cl, 4 dwg

Description

The invention relates to the gas industry, and in particular to the transport of natural gas over significant distances, and can be used at compressor stations that increase the pressure of natural gas during its transportation.

There are various compressor stations containing gas-pumping devices, as well as a forced gas cooling system, which can be used as a cooling agent (see, for example, the Operator of gas pipelines. Reference manual, Moscow, Nedra, 1987, pp. 100-106) .

A compressor station is known in which natural gas from a gas pipeline is used as a cooling agent in a forced oil supply unit (see, for example, RU 2140016 C1, 10.20.1999).

A disadvantage of the known station is the low economic efficiency and complexity of the design, low profitability due to the reduction in gas transportation speed.

Various compressor stations are also known in which heat pumps are used for gas cooling (see, for example, RU 2125212 C1, 10.20.1999).

A disadvantage of such stations is also low efficiency due to the significant material consumption of the installation for cooling gas transportation due to the need to use an additional evaporator, which is installed on the main gas pipeline in front of the supercharger of the gas pumping unit.

The use of a heat pump with two refrigerant evaporators in a gas cooling unit with automatic control of the amount of heat taken from the gas flow both at the inlet and at the outlet of the supercharger of the gas pumping unit, reducing the power consumed for gas compression, leads to additional labor and material costs, which reduces the efficiency of the compressor station as a whole.

The closest in technical essence and the achieved result to the claimed invention is a compressor station, in which air transport gas coolers (AVO) are used for cooling the transported gas, which have a number of advantages over other types of heat exchangers: they are reliable in operation, environmentally friendly, simple enough connected to the compressor station piping. Due to the high numerical values of the finning coefficients (approximately 8–20) used at compressor stations of gas air heat treatment plants, which characterize the ratio of the external surface area to the surface area of smooth pipes, they have very developed external heat exchange surfaces (see also A. Kozachenko and others. Energy gas pipeline transport, Moscow, State Unitary Enterprise Publishing House and “Oil and Gas”, Gubkin Russian State University of Oil and Gas, 2001, p.135-143).

However, in the known constructions of compressor stations using ABO, the parameters of the beam of finned tubes of the heat exchange section of the ABO gas are not optimized enough, which leads to an increase in the material consumption of the bundle and the heat exchange section itself and, as a result, reduces the economic efficiency of the compressor station as a whole.

The objective of the present invention is to increase the efficiency of the compressor station while reducing labor and material costs and ensuring high rates of heat transfer, as well as reliability and durability.

The problem is solved due to the fact that the linear compressor station of the gas pipeline, according to the invention, is installed on the section of the main gas pipeline after the head compressor station between it and another linear compressor station or between linear compressor stations and includes gas pumping units connected at the inlet of the piping piping to the system preparation of at least the process gas and at the outlet with the installation of the cooling process gas and through the shut-off the valve, the inlet and outlet pipelines with a main gas pipeline, and the process gas cooling unit is equipped with at least one gas air cooling unit mainly consisting of at least two heat exchange sections, each heat exchange section of which is made with a multi-row bundle of finned one-way pipes that form within of each row in the projection onto a conventional plane normal to the flow vector of the external heat exchange medium supplied to the pipes, the cooling air flow and passing through the central longitudinal axis of the pipes of each row, sections of full aerodynamic opacity corresponding to projections onto the indicated plane of the pipes without taking into account fins, sections of full aerodynamic transparency, corresponding to projections onto the indicated plane of the gaps between the edges of adjacent pipes facing each other and sections of incomplete aerodynamic transparency, each limited on one side of a conditional straight line running along the tops of the ribs, and on the other hand, by the contour of the pipe body along the main ribs, and the specific ratio per unit area of the mentioned conditional plane of the total projection areas of these sections with different aerodynamic transparency in each row is respectively (0.85-1.15) :( 1.82-2.17) :( 1, 80-2.19).

A linear compressor station can be made with a parallel collector piping of gas-pumping units, containing a connection unit, including security, bypass, and inlet taps, and a cleaning unit can be placed behind the inlet crane, which is connected through the corresponding pipeline to the inlet of centrifugal full-pressure superchargers of gas-pumping units, which are the outlet valve and pipelines are connected to the gas air cooling apparatus, which also through the outlet and safety valves and pipelines can be connected to the main gas pipeline, while the bypass valve is made with a diameter smaller than the diameter of the inlet valve, and the nominal diameters of the pipelines can be made sequentially decreasing from the connection node to the inlet of centrifugal superchargers, and after centrifugal superchargers, at least after their outlet valves, - increasing to the diameter of the pipeline through which the gas enters the gas air-cooling apparatus and after exiting it into the main gas pipeline, the m It can be equipped with a comprehensive gas-dynamic protection made in the form of a system of check valves and candle valves, moreover, check valves can be installed on the outlet pipelines of each gas pumping unit and additionally on the output loop of the compressor station's process gas pipeline, and the plug valves can be installed in an amount exceeding at least one, the number of check valves and placed along the gas stream, the first in the installation area of the inlet valve with the possibility of the candle any combination of the positions of the inlet and / or reserve inlet taps, and the remaining candle valves can be connected to the piping process pipelines mainly in front of the check valves along the gas flow, that the piping is equipped with two jumpers with taps, one of which is external and is connected to the inlet pipe to the inlet valve and to the outlet pipeline after the outlet valve and is intended for the transit passage of gas through the main gas pipeline when the compressor station is turned off, and the second I am an internal jumper, technologically parallel to the first, connected at the inlet and at the outlet, respectively, after the inlet tap and in front of the outlet tap, designed to equalize the pressures in the plant’s process pipelines and to ensure the station’s operation in the “station ring” mode, while the pipeline cross-sectional area is second the jumper can be taken as a smaller cross-sectional area of the external jumper pipeline 2.5-7.0 times, and the cross-sectional area of the crane installed on the inner jumper is, of 0,075-0,25 crossing sectional area of the pipeline jumper.

At least part of the gas pumping units can be driven by a centrifugal supercharger from a gas turbine, the gas pumping unit can be made in the form of a stationary installation, mainly of the type GT-6-750 or GTK-16 manufactured by the Ural Motor Plant, or GT-700-5, or GT-700-6, or GTK-10, or GTK-10-2, or GTK-10-4 manufactured by the Nevsky Plant, the gas pumping unit is made with a gas turbine drive of a centrifugal supercharger containing a gas aviation turbine reconstructed for use in gas pumping units, for example, GPA-Ts-6.3 or GPA-Ts-6.3A, or GPA-Ts-6.3A, mainly with a D-336 engine, or GPA-Ts-6.3B, mainly with an engine D-336 or NK-14ST, or GP-Ts-16, or GP-Ts-16L brands, mainly with an AL-31ST or GPA-Ts-16A brand engine, mainly with an NK-38ST or GPA-Ts-25 brand engine , mainly with an engine of the NK-36ST brand, the gas pumping unit can be made with a gas turbine drive of a centrifugal supercharger in the form of a ship gas turbine installation, for example, according to the GPA-2.5 type, mainly with an engine GTG-2.5 or GPU-6 brand lem, mainly with a DT-71 or GPU-10A brand engine, mainly with a DN-70 or GPA-Ts-16S brand engine, mainly with a DG-90 or GPU-25 engine , mainly with an engine like DN-80.

At least part of the gas pumping units can be made electric mainly type STM-4000, or STD, or STD-12.5, or type AZ-4500-1500 or SGD-12.5.

At least part of the gas pumping units can be equipped with gas-compressor units with piston units, mainly of the type 10GK, or 10GKM, or 10GKN, or 10GKNA.

At least one gas pumping unit can be made with a full-pressure centrifugal gas blower with a compression ratio of from 1.45 to 1.51, preferably of the type N-196-1.45, or 650-21-1, or 820-21-1, either type Cooper-Bessemer type superchargers of grades 280-30 or 2BB-30, or Nuovo-Pignoni superchargers of grades PCL-802/24 or PCL-1001-40.

At least a part of the gas pumping units can be equipped with a recuperator installed predominantly directly behind the gas turbine installation in the exhaust gas outlet zone for utilizing the heat of the exhaust gases with heating of the air supplied to the turbine, and the recuperator can be made in the form of a regenerative air heater, mainly in the form of a monoblock with a cylinder-conical body, at least within the greater part of its length, or the recuperator can be made in the form of p generative air heater block type is preferably sectional block and communicates with the outlet of the gas turbine plant and the flue to the atmosphere with a diffuser portion for supplying hot gases to the heat exchange zone of a regenerative air heater and confuser output therefrom.

The process gas preparation system, as well as starting, and / or fuel and / or pulsed gas, may contain at least one cyclone type dust collector, or at least one cyclone type dust collector and at least one filter separator installed in series along the gas after a cyclone dust collector or a cyclone dust collector system, the filter separator may include at least two process sections having replaceable filters - a filter section designed for coagulation of liquid and retention mechanical particles, and the separation section, designed to complete the gas purification from moisture, and may also contain a condensate collector, a heating system, mainly electric, at least the lower part of the filter separator and is equipped with instrumentation.

Each heat-exchange section of the gas air-cooling apparatus may be of the horizontal type or the heat-exchange sections of the gas-air cooling apparatus are installed to form slopes.

A multi-row bundle of finned tubes of each heat-exchange section of an air-cooled gas cooling apparatus can be communicated through gas inlet and outlet chambers and gas supply and exhaust manifolds with technological pipelines of the station, while a multi-row bundle of tubes of a heat-exchange section can contain from two to fourteen rows, each heat-exchange section apparatus for air cooling of gas may include a vessel for external cooling medium with longitudinal side walls, transverse end walls formed by chambers the inlet and outlet of the in-pipe medium and the bottom formed by the bodies of the diffusers of the fans, which can be installed under the heat exchange sections, with one to six fans installed under each section, each fan can be placed in an aerodynamic protective casing containing a diffuser and a smooth entry manifold wherein the smooth entry collector can be made in a longitudinal section of variable curvature with a configuration at least from the side of the inner surface, for example, along the lemniscus those, and mainly round in plan, with the inlet mouth of the casing in the zone of transition of the collector into the diffuser can be made with a diameter of 0.6-0.95 of the width of the heat exchange section, and the diffuser of the casing of each fan can be made in its upper part in the zone adjoining the frame elements of the heat-exchange section with the configuration of the outlet edge contour, which makes it possible to connect to the corresponding frame contour elements of the section, and the fans can be made mainly of two- or three-blade and with an adjustable change in the angle of rotation of the blades, with a fan wheel drive predominantly direct, gearless from a low-speed electric motor, with a power of preferably 2.5-12.0 kW and a nominal speed of preferably 290-620 min ^-1 .

A linear compressor station can be equipped with a system of gas air-cooling apparatuses, which form a structural complex of at least one field of gas air-cooling apparatuses - “ABO field”, and can be performed with supporting structures integrated into a common spatial unit within the “ABO field” ”, Including with the possibility of partial support of the supporting structure of each subsequent apparatus for air cooling of gas on the supporting structure of the previous one.

The technical result provided by the invention consists in increasing the efficiency of a linear compressor station, reducing labor and material costs while ensuring high heat transfer rates and operational reliability by optimizing the parameters of a heat-exchange finned tube bundle used as part of a linear compressor station of a gas air-cooling apparatus, expressed in optimal the placement of pipes in the bundle due to the design of folded spacing elements used in the invention, the parameters of which They provide the possibility of optimizing also the heat exchange section itself due to a denser arrangement of finned tubes in the bundle, while at the same time ensuring high heat transfer rates, reliability and durability.

The invention is illustrated by drawings, where

figure 1 shows a bundle of finned tubes of a heat exchange section of an air gas cooling apparatus;

figure 2 - node a in figure 1, showing the location of the finned heat transfer tubes in a row of the beam;

figure 3 - finned heat transfer tube bundle, fragment;

figure 4 - node B in figure 3.

The linear compressor station of the gas pipeline is installed on the section of the main gas pipeline after the head compressor station between it and another linear compressor station or between the linear compressor stations and includes gas pumping units (not shown in the drawings) connected at the inlet by process pipelines (not shown in the drawings) to the system preparation of at least a process gas and at the outlet with a process gas cooling installation (not shown in the drawings) and through a shut-off valve fittings (not shown in the drawings), inlet and outlet pipelines (not shown in the drawings) with a gas main (not shown in the drawings).

The process gas cooling unit is equipped with at least one predominantly composed of at least two heat exchange sections 1 gas air cooling apparatus (not shown in the drawings), each heat exchange section 1 of which is made with a multi-row bundle of finned one-way pipes 2, which form within each row 3 in a projection onto a conditional plane normal to the flow vector of the external heat exchange medium supplied to the pipes 2, - a cooling air flow and passing through the central longitudinal axis of the pipes 2 of each row 3, sections of total aerodynamic opacity 4, corresponding to projections onto the indicated plane of the pipes 2 without taking into account the fins 5, sections of full aerodynamic transparency 6, corresponding to projections onto the indicated plane of the gaps between the edges of the edges 7 of the adjacent 7 pipes 3, 2 and sections of incomplete aerodynamic transparency 8, each limited on one side of a conditional straight line passing through the vertices 9 of the ribs 7, and on the other hand, by the outline of the pipe body 2 along the bases of 10 ribs 7.

The specific ratio per unit area of the mentioned conditional plane of the total projection areas of the indicated sections 4, 6, 8 with different aerodynamic transparency in each row 3 is respectively (0.85-1.15) :( 1.82-2.17) :( 1 , 80-2.19).

A linear compressor station can be made with a parallel collector piping (not shown in the drawings) of gas pumping units containing a connection unit (not shown in the drawings), including security, bypass, input valves (not shown in the drawings).

Behind the inlet valve, a cleaning unit (not shown in the drawings) can be placed, which is connected through the corresponding pipeline to the inlet of centrifugal full-pressure superchargers (not shown in the drawings) of gas pumping units, which are connected through the outlet valve and pipelines to the gas air cooling apparatus, which is also through output and safety taps and pipelines can be connected to the main gas pipeline.

The bypass valve is made with a diameter smaller than the diameter of the inlet valve, and the nominal diameters of the pipelines can be made sequentially decreasing from the connection unit to the inlet of the centrifugal superchargers, and after centrifugal superchargers, at least after their outlet valves, increasing to the diameter of the pipeline through which the gas enters the gas air cooling apparatus and after exiting it into the main gas pipeline.

The strapping can be equipped with a comprehensive gas-dynamic protection made in the form of a system of check valves (not shown in the drawings) and candle valves (not shown in the drawings), and check valves can be installed on the outlet gas pipelines (not shown) of each gas pumping unit and additionally on the output loop of the compressor station's process gas pipeline, and the candle taps can be installed in an amount exceeding at least one number of check valves and placed along the gas of the flow, the first in the installation area of the inlet valve with the possibility of operation of the plug for any combination of the positions of the inlet and / or backup inlet valves, and the remaining candle valves can be connected to the piping process piping, mainly in front of the check valves along the gas stream, that the piping is equipped with two jumpers with taps (not shown in the drawings), one of which is external and is connected to the inlet pipe to the inlet crane and to the outlet pipe after the outlet crane and is intended and for gas transit through the main gas pipeline when the compressor station is turned off, and the second internal jumper, technologically parallel to the first, is connected at the inlet and at the outlet, respectively, after the inlet valve and in front of the outlet valve, it is used to equalize the pressures in the station's technological pipelines and to ensure the operation of the station in the "station ring" mode.

The cross-sectional area of the pipeline of the second jumper can be taken to be 2.5-7.0 times smaller than the cross-sectional area of the pipeline of the external jumper, and the cross-sectional area of the tap installed on the internal jumper is 0.075-0.25 of the cross-sectional area of the pipeline of this jumper.

At least part of the gas-pumping units can be driven by a centrifugal supercharger (not shown in the drawings) from a gas turbine, the gas-pumping unit can be made in the form of a stationary installation (not shown in the drawings), mainly of the type GT-6-750 or GTK-16 manufactured by the Ural Motor Plant, or GT-700-5, or GT-700-6, or GTK-10, or GTK-10-2, or GTK-10-4 produced by the Nevsky Plant, the gas pumping unit is made with a gas turbine drive of a centrifugal supercharger ( not shown in the drawings), soda neighing a gas aviation turbine reconstructed for use in gas pumping units, for example, GPA-Ts-6.3 or GPA-Ts-6.3A, or GPA-Ts-6.3A, mainly with an engine of the D-336 or GPA-Ts brand -6.3B, mainly with an engine of the D-336 or NK-14ST brand, or GP-Ts-16, or GP-Ts-16L, mainly with an AL-31ST or GPA-Ts-16A brand engine, mainly with an NK brand engine -38CT or GPA-Ts-25, mainly with an engine of the NK-36ST brand, the gas pumping unit can be made with a gas turbine drive of a centrifugal supercharger in the form of a ship gas turbine installation (not shown in the drawings), for example, according to the GPA-2.5 type, mainly with an engine of the GTG-2.5 or GPU-6 brand, mainly with an engine of the DT-71 or GPU-10A brand, mainly with an engine of the DN brand -70 or GPA-Ts-16S, mainly with an engine of the DG-90 brand, or GPU-25, mainly with an engine of the DN-80 type.

At least part of the gas pumping units can be electric driven, mainly of the type STM-4000, or STD, or STD-12.5, or type A3-4500-1500 or SGD-12.5.

At least part of the gas pumping units can be equipped with gas-compressor units with piston units (not shown in the drawings), mainly of the type 10GK, or 10GKM, or 10GKN, or 10GKNA.

At least one gas pumping unit can be made with a full-pressure centrifugal gas blower with a compression ratio of from 1.45 to 1.51, preferably of the type N-196-1.45, or 650-21-1, or 820-21-1, either type Cooper-Bessemer type superchargers of grades 280-30, or 2BB-30, or Nuovo-Pignoni superchargers of PCL-802/24 or PCL-1001-40 grades.

At least a part of the gas pumping units can be equipped with a recuperator (mainly not shown) in the exhaust gas outlet area that is installed directly behind the gas turbine unit (not shown) to utilize the heat of the exhaust gases with heating of the air supplied to the turbine, and the recuperator can be made in the form of a regenerative air heater, mainly in the form of a monoblock (not shown in the drawings) with a cylinder-conical body, at least in pre most of its length, or the recuperator can be made in the form of a regenerative air heater of a block type (not shown in the drawings), preferably sectional-block and connected to the outlet of the gas turbine unit and to the atmosphere by a gas duct with a diffuser in the area for supplying hot gases to the heat exchange zone of the regenerative air heater and confuser at the exit from it.

The process preparation system, as well as starting, and / or fuel, and / or pulsed gas, may contain at least one cyclone type dust collector (not shown in the drawings), or at least one cyclone type dust collector (not shown in the drawings) and at least one filter separator (not shown in the drawings) installed sequentially along the gas after the cyclone dust collector or cyclone dust collector system, the filter separator may include at least two technologically replaceable filters x sections - filtering, designed to coagulate liquid and trapping mechanical particles, and a separation section, designed to complete gas purification from moisture, and may also contain a condensate collector (not shown in the drawings), a heating system (not shown in the drawings), mainly electric, at least the bottom of the filter separator and is equipped with instrumentation (not shown in the drawings).

Each heat-exchange section 1 of the gas air-cooling apparatus may be of the horizontal type or the heat-exchange sections 1 of the gas-air cooling apparatus are installed to form slopes.

A multi-row bundle of finned tubes 2 of each heat exchange section 1 of an air-cooled gas cooling apparatus can be communicated through gas inlet and outlet chambers (not shown in the drawings) and gas supply and exhaust manifolds (not shown in the drawings) with the plant pipelines, while a multi-row tube bundle 2 of the heat exchange section 1 may contain from two to fourteen rows 3.

Each heat exchange section 1 of the gas air cooling apparatus may include a vessel for external cooling medium with longitudinal side walls, transverse end walls formed by inlet and outlet chambers of the in-pipe medium and a bottom formed by diffuser bodies (not shown in the drawings) fans (not shown) that can be installed under the heat exchange sections.

One to six fans are installed under each section (not shown in the drawings), each fan can be placed in an aerodynamic protective casing (not shown in the drawings) containing a diffuser and a smooth entry manifold (not shown in the drawings).

The smooth entry collector can be made in a longitudinal section of variable curvature with a configuration, at least from the side of the inner surface, for example, along the lemniscate, and mainly round in plan, and the entrance mouth of the casing in the zone of transition of the collector to the diffuser can be made with a diameter of 0 , 6-0.95 width of the heat exchange section.

The diffuser of the casing of each fan can be made in its upper part in the area adjacent to the frame elements of the heat-exchange section with the configuration of the outlet edge contour, which makes it possible to connect the section frame to the corresponding circuit elements.

Fans can be made predominantly two- or three-bladed and with an adjustable change in the angle of rotation of the blades, with the drive of the fan wheel mainly direct, gearless from a low-speed electric motor, its power component preferably 2.5-12.0 kW and rated speed preferably 290-620 min ^-1 .

A linear compressor station can be equipped with a system of gas air-cooling devices (not shown in the drawings), forming a structural complex integrated into at least one field of gas air-cooling devices - “air cooler field”, and can be performed with supporting structures (in the drawings not shown), combined into a common spatial unit within the "ABO field", including with the possibility of partial support of the supporting structure of each subsequent gas air cooling apparatus to the supporting structure tion of the previous one.

The linear compressor station of the gas pipeline operates as follows.

When the gas moves due to various kinds of hydraulic resistance along the length of the pipeline, its pressure drops, which leads to a decrease in the throughput of the gas pipeline. Therefore, it is impossible to transport gas in sufficient quantities and over long distances only due to natural reservoir pressure. Compressor stations are used to maintain a given flow rate of the transported gas and ensure its optimal pressure in the pipeline.

During the extraction and transportation of natural gas, it almost always contains various kinds of impurities: sand, weld sludge, condensate of heavy hydrocarbons, water, oil, etc. The main source of natural gas pollution is the bottomhole zone of the well, which gradually degrades and pollutes gas; therefore, before the gas is supplied to the gas pumping units that are part of the compressor station, the inlet gas passes through a preparation system that, depending on the specific conditions, contains various treatment facilities, for example cyclone dust collectors, filters - separators, etc. The energy intensity of natural gas transport is mainly determined by the energy intensity of the process of moving gas through the pipeline. To reduce these energy costs, it is necessary to lower the temperature of the transported gas, increase its pressure and cool the gas after compression. So when cooling gas in a gas pipeline, for example from 50-55 ° C to 25-30 ° C, the throughput of the gas pipeline can be increased by 4-5%. The gas enters the cooling unit, equipped with at least one predominantly consisting of at least two heat-exchange sections gas air cooling apparatus. Passing through a multi-row single-pass bundle of finned tubes made in accordance with the developed invention, the gas is cooled by the action of fans supplied from below into the annulus. Considering that the gas air cooling apparatus is one of the main and necessary technological units of the compressor station, it is obvious that the gas cooling efficiency is decisive for the efficiency of the compressor station, in accordance with which the optimization of the finning parameters of the heat exchange tubes in the bundle, ensuring an increase in the gas cooling process by increasing the thermo-aerodynamic characteristics, improving the conditions of flow around the beam tubes with a working medium, increasing the life of the beam heat exchange tubes by ensuring rigidity and stability of the beam while eliminating the engagement of the edges of the pipes of adjacent rows and the absence of violations of the uniform cross-section for the cooling air, increasing the heat transfer coefficient of the surface of the finned pipes from the cooling air, increasing the packing density of the pipes in the bundle, contributes to the efficiency of the gas supply system in whole.

Claims (11)

1. A linear compressor station of a gas pipeline, characterized in that it is installed on a section of the main gas pipeline after the head compressor station between it and another linear compressor station or between linear compressor stations and includes gas pumping units connected at the inlet by piping pipelines with a preparation system, at least at least the process gas and at the outlet with the installation of the process gas cooling and through shut-off valves, inlet and outlet pipes pipelines with a gas main, and the process gas cooling unit is equipped with at least one, mainly consisting of at least two heat exchange sections, gas air cooling apparatus, each heat exchange section of which is made with a multi-row bundle of finned one-way pipes that form within each row in projection onto a conventional plane normal to the flow vector of the external heat exchange medium supplied to the pipes — the cooling air flow — and passing through the central the longitudinal axis of the pipes of each row, the sections of full aerodynamic opacity corresponding to the projections onto the indicated plane of the pipes without taking into account the fins, the sections of full aerodynamic transparency, corresponding to the projections onto the indicated plane of the gaps between the edges of the edges of adjacent pipes facing each other, and the sections of incomplete aerodynamic transparency, each bounded on one side by a conditional line passing along the vertices of the ribs, and on the other hand, by the contour of the pipe body along the bases of the ribs, and the specific the ratio per unit area of the mentioned conditional plane of the total projection areas of these sections with different aerodynamic transparency in each row is respectively (0.85-1.15) :( 1.82-2.17) :( 1.80-2.19) . 2. The linear compressor station according to claim 1, characterized in that it is made with a parallel collector piping of gas pumping units, containing a connection unit, including security, bypass, inlet taps, and a cleaning unit is placed behind the inlet tap, which is connected to the inlet through a corresponding pipeline centrifugal full-pressure superchargers of gas-pumping units, which are connected through the outlet valve and pipelines to the gas air cooling apparatus, which is also through the outlet and ocher The taps and pipelines are connected to the main gas pipeline, while the bypass valve is made with a diameter smaller than the diameter of the inlet valve, and the nominal diameters of the pipelines are successively decreasing from the connection node to the inlet of the centrifugal superchargers, and after centrifugal superchargers, at least after their outlet taps, increasing to the diameter of the pipeline through which gas enters the gas air-cooling apparatus and after exiting it into the main gas pipeline, and the piping is equipped with multiplex gas-dynamic protection made in the form of a system of check valves and candle valves, moreover, check valves are installed on the outlet pipelines of each gas pumping unit and additionally on the output loop of the compressor station technological gas pipeline, and the plug valves are installed in an amount exceeding at least one number check valves and are placed along the gas flow, the first - in the installation area of the inlet crane with the possibility of the candle for any combination of inlet and / or backup inlet taps, and the remaining candle taps are connected to the piping process pipelines mainly in front of the check valves along the gas flow, that the piping is equipped with two jumpers with taps, one of which is external and connected to the inlet pipe to the inlet crane and to the outlet pipe after the outlet crane and is designed for gas transit through the main gas pipeline when the compressor station is turned off, and the second internal jumper, technologically parallel the first, connected at the inlet and at the outlet, respectively, after the inlet tap and in front of the outlet tap, is designed to equalize the pressures in the technological pipelines of the station and to ensure the operation of the station in the “station ring” mode, while the cross-sectional area of the pipeline of the second jumper is taken smaller the cross-sectional area of the pipeline of the external jumper is 2.5-7.0 times, and the cross-sectional area of the tap installed on the internal jumper is 0.075-0.25 of the cross-sectional area of the pipe gadfly this jumper. 3. The linear compressor station according to claim 1, characterized in that at least a portion of the gas pumping units are driven by a centrifugal blower from a gas turbine, the gas pumping unit is made in the form of a stationary installation, or the gas pumping unit is made with a gas turbine drive of a centrifugal blower, containing gas aviation turbine, reconstructed for use in gas pumping units, gas pumping unit is made with a gas turbine driven centrifugal pump ator of the ship's gas turbine plant. 4. The linear compressor station according to claim 1, characterized in that at least a portion of the gas pumping units are electrically driven. 5. The linear compressor station according to claim 1, characterized in that at least part of the gas pumping units are equipped with gas compressor units with piston units. 6. The linear compressor station according to claim 1, characterized in that at least one gas pumping unit is made with a full-pressure centrifugal gas blower with a compression ratio from 1.45 to 1.51. 7. The linear compressor station according to claim 1, characterized in that at least a portion of the gas pumping units is provided with a recuperator installed predominantly directly behind the gas turbine unit in the exhaust hot gas exit zone for utilizing the heat of the exhaust gases with heating of the air supplied to the turbine, the recuperator is made in the form of a regenerative air heater, mainly in the form of a monoblock with a cylinder-conical body, at least within most of its length, or the recuperator is made in the form of a regenerative air heater of a block type, preferably sectional-block and is in communication with the outlet of the gas turbine unit and with the atmosphere through a gas duct with a diffuser at the hot gas supply to the heat exchange zone of the regenerative air heater and a confuser at the outlet from it. 8. The linear compressor station according to claim 1, characterized in that the preparation system of the process, as well as starting, and / or fuel, and / or pulsed gas contains at least one cyclone type dust collector or at least one dust collector cyclone type and at least one filter separator installed sequentially along the gas after the cyclone dust collector or cyclone dust collector system, and the filter separator includes at least two process sections having replaceable filters - a filter section, Designed to coagulate liquid and trap mechanical particles, and a separation section designed to complete the gas purification from moisture, it also contains a condensate collector, a heating system, mainly electric, at least the lower part of the filter separator, and is equipped with instrumentation. 9. The linear compressor station according to claim 1, characterized in that each heat exchange section of the gas air-cooling apparatus is made of a horizontal type, or the heat-exchange sections of the gas air-cooling apparatus are installed with the formation of slopes. 10. The linear compressor station according to claim 1, characterized in that the multi-row bundle of finned tubes of each heat exchange section of the gas air-cooling apparatus is communicated through gas inlet and outlet chambers and gas supply and exhaust manifolds with the plant process pipelines, wherein the multi-row tube bundle of the heat exchange section contains from two to fourteen rows, and each heat-exchange section of the gas air-cooling apparatus includes a vessel for external cooling medium with longitudinal side walls transverse to the end walls formed by the inlet and outlet chambers of the in-pipe medium and the bottom formed by the fan diffuser bodies, which are installed under the heat-exchange sections, and from one to six fans are installed under each section, and each fan is placed in an aerodynamic protective casing containing a diffuser and a smooth collector entrance, while the smooth entry collector is made in a longitudinal section of variable curvature with a configuration at least from the side of the inner surface, for example, along niskata and mainly round in plan, with the inlet mouth of the casing in the zone of transition of the collector to the diffuser made with a diameter of 0.6-0.95 width of the heat exchange section, and the diffuser of the casing of each fan is made in its upper part in the area adjacent to the elements of the heat transfer frame sections with the configuration of the contour of the output edge, providing the ability to connect to the corresponding elements of the contour of the frame of the section, and the fans are made mainly of two - or three-blade and with adjustable change the angle of rotation of the blades, with the fan wheel driven, preferably straight, from a low-speed gearless motor, its power is preferably 2,5-12,0 kW and the nominal rotational speed is preferably 290-620 min ^-1. 11. The linear compressor station according to claim 1, characterized in that it is equipped with a system of gas air-cooling apparatuses, forming a structural complex combined, at least in one field of gas air-cooling apparatuses - "field ABO", and is made with supporting structures, combined into a common spatial block within the "ABO field", including with the possibility of partial support of the supporting structure of each subsequent gas air cooling apparatus to the supporting structure of the previous one.

Images